An Analysis of a Peat Profile - Analytical Chemistry (ACS Publications)

Reinhardt Thiessen, R. C. Johnson. Ind. Eng. Chem. Anal. Ed. , 1929, 1 (4), pp 216–220. DOI: 10.1021/ac50068a020. Publication Date: October 1929...
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VOl. 1, No. 4

ANALYTICAL EDITION

216 Sensitivity of S t a r c h Reagent (2 cc. used) WATER

cc.

200" 200 200 200

DEPRESSANT USED SALT

Grams KI 0.40 KI 1.0 KI 5.0

w/soo F

IODINE

1 cc.

To

~

0.4

0.4

0.2

NaCl 0 . 5 l.Q NaCl 1 . 0 1.8 NaCl 5 . 0 1.6 200 KRr 5 . 0 3.2 200 No salt present 3.6 0.26 cc. of coucd. HrSOl added, ?"hi& is approxin1ately the amount present in the Winklcr titration.

It will be noted that if the amount of potassium iodide present equals that present in the Winkler titration, only 0.02 iodine solution would be required to pro& cc. ~of a N/40 ~ ~ ~ ~ ~ duce the first permanent blue color or an equal quantity of N/40 thiosulfate solution to discharge the last trace of blue color. This is easily within the limits of experimental error.

200 200

Literature Cited (1) Treadwell arid Hall, "Analytical Chenxistrp," Val. I , p. ZQQ (1914). (2) I b i d . , Vol. 11, p. 653.

An Analysis of a Peat Profilels2 Reinhardt Thiessen and R. C. Johnsons PITTSBURGH EXPERIMENT STATION, U. S. BUREAU OF MINES,PITTSBURGH, PA

Since coal was formed in a similar manner as peat is being formed today and a t one time was in the peat stage, a better knowledge of the nature and chemistry of peat should add to a better knowledge of the nature and chemistry of coal. Peat formation is largely a microbiological problem, and may be considered under three phases: in the air, partly submerged, and completely submerged. All classes of plants and every plant product must be considered. The microbiological reactions in the first phase are aerobic ; and fungi, actinomyces, bacteria, burrowing insects, Crustacea, and other lower forms of life are instrumental in reducing the plant substances into a more or less decayed and macerated state. The second stage is transitional and only bacteria and some actinomyces remain active. In this shallow zone much living plant matter, mostly lignin and cellulose, in the form of roots, is added. In the third and permanent stage anaerobic bacteria only function. It has been demonstrated that bacteria exist and are active a t all depths. Theoretically, therefore, changes should occur in a peat deposit after its deposition. To answer this, analyses of samples from a peat profile were made with respect to relative amounts and nature of the major components such as water-soluble matter, ether-soluble matter,

humins, lignin, cellulose, and insoluble residues consisting mostly of spore, pollen, and cuticle matter. This offered a t the same time a relation of the various components and the changes they have undergone during the period of their existence. Since the inception of the deposit dates from a time soon after the last ice age, considerable time must have elapsed, with proportionally less time for the successive younger layers until the present. The analyses given in the tables and figures show that lignin and cellulose decrease with the depth of the deposit and hence with age, and the humins increase with the depth and hence with age. There was, therefore, a progressive humification with age. Because too many unknown factors enter into the time changes, on account of large mixtures of the original contributory plant products, no solution is offered by these analyses as to whether lignin is the chief contributor, or whether both lignin and cellulose contribute in more equal proportions. The different floras that prevailed successively during the deposition of the peat mass caused different and specific types of peat to be laid down; successive layers give chemically different types of peat and these are reflected in the curves as fluctuations.

........ . . . . . .

I

T IS generally agreed that coal is of plant origin and was

formed in a manner similar to that in which peat is being formed today. A thorough study of peat from its inception to the more mature stages a t its greatest depth becomes essential to the understanding of the constitution of coal and its formation. With this objective a study was undertaken of the transformation of plant substances into peat and the composition of a deposit in profile from top to bottom with respect to its major components, their nature, their changes, and their relations. By such a study it is hoped to discover more definitely what plant substances contributed to coal and what are now their chemical and physical natures. A work of this kind includes the study and consideration I Presented before the Division of Gas and Fuel Chemistry a t the 77th Meeting of the American Chemical Society, Columbus, Ohio, April 29 to May 3, 1929. a Published by permission of the Director, U. S. Bureau of Mines and of the Carnegie Institute of Technology and the Mining Advisory Board. (Not subject to copyright.) 3 Formerly research fellow Carneaie In.;titute o i Technology

of every compound and product of all plants. The chemistry of plant substances is remarkably well known. Only one chief and important constituent, lignin, defies solution. This is unfortunate, as it is the most important contributor to peat and coal. The study also involves the chemistry of decay, the action of fungi, bacteria, actinomyces, burrowing insects, and other lower organisms. During the last ten years much has also been learned of the chemistry of decay (4); much, however, is yet to be learned. With these available data the composition of peat can in some measure be postulated; yet many questions and problems remain unanswered. The Bog The peat on which these studies were carried out was obtained from a wooded swamp in Manitowoc County. Wis., known as Hawk Island Swamp. This is a typical wooded swamp of which there are a considerable number, formed by uneven deposits of gravel after the retreat of the last ice age. It is of considerable area and is covered with

INDUSTRIAL AND ENGINEERING CHEMISTRY

October 15, 1929

Dry constant weight Cold HzO, 200 c. c. ; 48 hours Soluble Ash Organic material Insoluble

Insoluble

Hot H20, 150 C. c.; 5 hours Soluble

Ether 8 hours Ash Organic material Soxhlet

217

water and debris and deprived of free access of air; and (3) a stage between these two under more or less fluctuating conditions. The most important changes and 'eliminations during the transformation of plant substances into peat occur in the first stage, while the plant substances are still exposed to free access of air. Immediately after the plant products or plant parts have separated from the parent plants, or after the death of the whole plant itself, they are attacked by fungi, actinomyces, bacteria, insects, and other lower organisms. These, together with the dynamic agencies of the atmosphere, reduce the plant substances to a semi-decayed, more or less disintegrated mass. As the mass is more and more covered with subsequent debris, the activity of the microorganisms changes through elimination of the more strictly aerobic forms, until finally faculative aerobic bacteria remain. This is also the shallow zone permeated with the root of the flora of the swamp. Finally, when the debris is completely submerged and the permanent deposit is established, all organisms except anaerobic bacteria have ceased to function. Bacteria in Peat

Dried, weighed Chlorine dioxide

Fats, waxes, resins

Insoluble

Soluble

Insoluble

Cupric ammoniacal solution Soluble

Large samples were taken from top to bottom in the form of columns 0.61 meter (24 inches) in length and about 0.51 by 0.51 meter (20 by 20 inches) square; these were shipped to the laboratory a t Pittsburgh. The natural condition of the peat mass was thus preserved and every phase of peat formation could be studied without having disturbed the original characteristics. The surface layer consists of semi-decayed logs, twigs, and branches, and fragments thereof in every conceivable size, together with the residue of the surface flora, and in every stage of decomposition and maceration. Slightly beneath the surface is a shallow zone penetrated with a dense mass of roots and rootlets of the plants now growing on it. The next 1.22 meters (4 feet) are composed of a woody peat derived from material such as is now found on the surface. At the lower horizon of the woody peat it becomes increasingly mingled with moss residues, which rapidly develop into a typical moss-peat about 0.30 meter (12 inches) in depth. The next 0.91 to 1.52 meters (3 to 5 feet) consist of a reed-sedge-grass peat, the products of a marsh stage. The last 0.30 meter (12 inches) of peat a t the bottom consists chiefly of a highly macerated mass, the product of an open-water stage. The entire deposit is, however, sublayered owing to slight differences in plant societies and degree of decay and maceration. Agents of Decay Peat formation is largely a problem of microbiology. It may roughly be divided into three stages: (1) in the air .with free access of air; (2) completely submerged under

It has now been satisfactorily proved that bacteria exist in peat and are functioning to all depths of the deposit. A large number of inoculations have been made from the top to the bottom of several peat deposits, and it is rare that cultures are not obtained. These cultures are being propagated on wood in the form of sawdust and shavings, on cellulose, and on other plant materials contained in flasks and bottles with proper mineral culture solutions; they are still active after 7 to 19 months. Available nitrogen is essential for their activities. From these observations it may be deduced that further changes, generally termed "humifications," are going on in the formed deposit, but this had as yet not actually been demonstrated. To prove definitely the further influence of bacteria on peat after its deposition, and the further humification, analyses were made from top to bottom with respect to its major

1Ether 6 to 8 hours in HzSO3; 300 c. c. autoclave, 12 hours

Fats, waxes, resins

4:; Lignin soluble

2 grams 300 C. 2N.NH40H 3 to 4 days 3 to 5 hours in autoclave

Soluble humic material

Insoluble iolpble

I

Iniol,uble

Precipitated with 95 per cent C ~ H R O H

1Furfural

Aih -

Washed with ACI and NaOH Figure 2-Sven

Oden's Method of Analysis of P e a t

components-namely, water-soluble matter, ether-soluble material, humins, lignin, cellulose, and certain insoluble constituents. From the large samples shipped from the field small lumps were selected at 3-inch (7.6-cm.) intervals for the first 2 feet (6.1 meters) and at 6-inch (15-cm.) intervals for the remainder of the depth, and dried at 105" C. From this series &grain samples were selected.

ANALYTICAL EDITION

218

g 2

E

0 DEPTH, METERS Figure 3-Ether-Soluble Material in Peat

4

g 3

P

;2

8 31 0

Figure 4-Lignin

DEPTH, METERS Content of Peat i n Relation to Depth

..

Figure 5-Humic

Matter i n Peat i n Relation to Depth

M e t h o d s of Analysis of Peat

Two methods of analysis were used-one developed by Sven O d h (6), and the other adapted and developed after various authors. Each method was run in duplicate. Either of these two methods is far from being completely satisfactory, and exact separation of all the components cannot be expected, but they serve to separate the components into rather well-defined groups. Duplicate analyses checked fairly well. Following is the procedure of the adopted method, referred to as the “chlorine dioxide method,” and Figures I and 2 give an idea of the successive steps: COLD-WATER EXTRACT-A 5-gram sample, after being dried to a constant weight a t 105’ C., is treated with distilled water a t room temperature for 48 hours, and filtered. The amount of organic matter and ash is determined in the filtrate. HOT-WATER ExTRAcT-The residue of the cold-water extract is refluxed 3 hours with 150 cc. of distilled water, filtered, and the ash and organic matter determined in the filtrate. ETHERExTuc-The residue of the hot-water extract is refluxed 8 hours in a Soxhlet with ether; the residue is dried and weighed and the extract determined by difference. LIGNINDETERMINATION-The residue of the ether extract is then treated with 200 cc. of approximately 1.5 N chlorine dioxide solution a t room temperature for 48 hours, filtered, and washed until free from chlorine. This is repeated until the chlorine dioxide solution is no longer colored. The residue is dried and

Vol. 1, No. 4

weighed and the difference calculated as lignin content. The ash is determined in the filtrate and corrections made. HUMICMATTER-The dried and weighed residue of the lignin extract is now treated 5 days with 2 N solution of ammonium hydroxide followed by heating to 110” C. for 3 hours under 15 pounds (1 atmosphere) pressure in an autoclave. It is then filtered through a Gooch crucible, washed, dried, and weighed; the humic matter is determined by difference. CEtLuLosE-The residue is then treated with 100 cc. of Schweizer’s reagent (Dawson’s modification) (7) for 5 hours, filtered, and washed. The cellulose in the filtrate is precipitated with 95 per cent alcohol, filtered, and washed with dilute hydrochloric acid followed by dilute alkali; corrections are made for ash. INSOLUBLE MATTER-The residue constitutes insoluble organic matter and ash.

The OdCn method is carried out in a similar manner except that no water-soluble matter is separated and lignin is extracted with sulfurous acid. Discussion of Results

Tables I and I1 give results of the analyses by the two methods. WATER-SOLUBLE MATTER-The cold-wa t ersoluble matter in peat ranges between 1 and 3 per cent, increasing from top to bottom. The hot-water-soluble matter, as may be expected, is considerably higher being highest with 4.25 per cent near the surface and fairly constant below the first 0.30 meter (12 inches) at 3.50 to 4 per cent. The water-soluble matter contains considerable amounts of reducing sugars, pentosans, methyl pentosans, nitrogenous compounds, and humic m a t t e r (IO). The pentosan contents fluctuate irregularly between 2.13 to 4.44 per cent. The total reducing sugars irregularly increase from 3.65 per cent at the top to 13.88 per cent a t the 2.44-meter (8-foot) level. This increase is yet to be explained. ETHER-SOLUBLE MATTER-The ether-soluble matter, as seen in the tables and in Figure 3, remains fairly constant from top to near the bottom, fluctuating irregularly between approximately 2 and 6.6 per cent and becoming higher in the last 0.30 meter (12 inches). The ether-soluble matter contains chiefly fats, waxes, and resins. The color of the extract varies from brown at the top to greenish brown at the bottom. They are soluble in a hot ether or alcohol-benzene mixture, but are insoluble in the cold liquor. The crude ether-soluble matter may be separated into a benzene-soluble brown fraction and an ether-soluble green wax. I n solution this purified wax has a green color much resembling alcoholic solution of chlorophyll. On cooling and evaporation it crystallizes out in a green mass which, on drying on a water bath, assumes a dark green color. It has a melting point of 83” to 84” C. and a saponification value of 216; its acid number is 63.79 and its ester number is 152.21. Though this wax resembles the montan waxes in general, it more closely resembles a wax isolated from Irish peat ( I ) , except that its saponification number is higher. LIGNINCONTENT-The greatest importance and interest is centered around the lignin, cellulose, and humin contents. The relation of the relative amounts of these three components gives an index of the changes, generally termed “humification,” going on in the deposit as time advances. This group also involves the much debated question as to the origin of humins; one school maintains that lignin alone, or pri-

INDUSTRIAL AND ENGINEERING CHEMISTRY

October 15, 1929

marily (e), is the source of humin; another maintains that lignin and cellulose contribute in more equal proportions (6). Not many years ago cellulose alone was considered; evidence now points in the direction that cellulose contributes only indirectly and then in small amounts (8). Table I-Analysis HOTWATER DEPTH SOLUBLEa Inches Meters % ’

3 6 9 12 15 15 21 24 30 42 36 48 54 60 72 66 78 84 90 102 96 108 114 120

0.076 0.15 0.23 0.30 0.35 0,45

0.53 0.61 0.76 0.91 1.06 1.22 1.37 1.52 1.67 1.83 1.98 2.13 2.28 2.44 2.59 2.74 2.89 3.04

of Peat by Chlorine Dioxide Method

2:48

.. ..

4:Z5

..

5.80 3:55 3.08 4:46 2:3 1:3 0:9 ..

.. ..

3%0 N H a O H d % % 36.50 9.9 21.30 15.15 15.12 14.60 11.50 17.30 33,4 ... 1i:67

ER’SB

3.45 1.39 1.34 7.25 8.57 4.66 2.96 2.92

41.3 22.3 29.6 21.3 16.4 27.7 20.3 20.16

14.46 10.41 7.35 23.71 9.58 30.54

1.66 3.47 1.84

23.95

2.21 4.45

BLEj

%

%

24.97 38.85 38.81 33.02

4.1 8.46 12.93 12.77 2i:j3 9,46

...

15.53 32.10 18.00 35.4 33.2 38.54 35.75 31.02

6.85 5.01 20.39

14.36 19.52 15.36

31.12 38.6 19.43 35.91

10.12 4.03 2.17

20.19 24.06

15.75 49,50 18.25 47.8 10.00 51.05

1 03

18.26 19.36 20.40

:::: $:::::!:;! 1 !l ::: ig i;::! I-.53

..

SOLU-

SCHWEIZ-

% 1.8 3.77 3.83 5,28

SOLUBLEb

..



IN-

ETHER- ClOz-

i!:;:

30.2

: :! .. ,... ~

Hexosans, pentosans. humins, starches, gums, organic nitrogen, and amines. b Fats, waxes, and resins. c Lignin and pentosans. d Humic matter. e Cellulose. f Spores and cuticles. Q

Table 11-Analysis

.

of Peat by Od&’s Method SCHWEIZER’Sd

CUPRIC AMMO-

ETHERNIACAL SOLUBLE~ H a S O a b N H ~ O H G SOLN. Meters % % % %

SOLUBLEe

DEPTH

Inches

3 6 9 12 15 18 21 24 30 36 42 48

54 60 66 72

78

84 90 96 102 108 114 120

0.08 0.15 0.23 0.30 0.38 0.45 0.53 0.61 0.76 0.91 1.06 1.22 1.37 1.52 1.67 1.83 1.98 2.13 2.28 2.44 2.59 2.74 2.89 3.04

2.89 3.01 3.22 4.13 2.95 2.80, 3.88 2.88 2.80 5.96 4.2 3.68 2.69 1.95 2.2 2.1 0.84 1.51 1.67 3.17 0.61 3.5 4.2 6.6

%

7.01 19.62 21.83 22.84 12.2 25.02 30.84 39.16 43.93

44.73 38.51 37.15 40.53 23.3 11.27 9.03 11.63 7.18

2.0 10.62 15.23 12.07 9.03 18.31 21.05 18.53

20:32 15.12 17.52 10.28 18.63 11.7 17.56 34.20 21.81 17.36

45:87 53.2 51.78 56.38 50.21 43.98 50.2 47.29 54.6 59.8 53 7 65:80 60.28 61.03

5.01 3.58 18.23 22.08 10.36

23:35 25.20 9.37 10.82 15.64 20.18 10.36 15.30 20.35 18.43 21.06 23.46 26.32 28.35

16:h 13.06 15.20

. ..

4.83 1.08 2.01 0.00 0.00

2.16

. ..

0.00

As shown by Tables I and I1 and Figure 5, the curves of the humic contents are definitely related in reverse order to that of the lignin curves. It starts with a low figure (between 8 and 10 per cent) in the surface layer, and gradzally rises to the bottom of the woody peat zone with over 50 per cent, taking a slight downward turn in the moss-peat zone, again taking an upward turn in the grass-sedge-reed peat, and gradually rising to a high point of above 60 per cent at the bottom. It should be remembered that the.curves of the data obtained by Od6n’s method include the water-soluble humins as well as certain hexosans and pentosans; therefore they are relatively higher ( 3 ) . The humic material, as separated from peat with 2 N ammonium hydroxide, is far from being a unit substance; in fact, it is a heterogeneous substance and can be separated into a number of fractions, as follows: (1) a water-soluble fraction called fulvic acid; (2) a hot-alcohol-soluble fraction called hymatomelanic acid; and (3) an insoluble fraction, the humic acid proper. The last fraction may again be separated into a sodium carbonate-soluble and a sodium carbonate-insoluble fraction. The sodium carbonate-soluble fraction, precipitated with hydrochloric acid, is further separable with pyridine into a soluble and insoluble fraction. The hot-alcohol fraction, or hymatomelanic acid, on Cooling separates out into a wax with a melting point of 79” C. after filtering and desiccating the filtrate. A resin acid is dissolved out with ether. Peat

1

Soluble Lignin 63.2 per cent

c102

Residue 2 per cent NaOH or 4 per cent N H 4 0 H

IN-

42.3 27.3 23.6 21.7 52.6 43.4 34.8 38.3 16.7

...

219

. ..

Fats, waxes, and resins. b Lignin. E Humic matter. d Cellulose. e Spores and cuticles.

Humic materials

Water solubte 4.5

Soluble

precipitates out

Ether-soluble acids

s , e

,

a

As may be expected, because the surface layer contains much sound woody matter, chiefly in the form of roots and semi-rotten stem fragments, the lignin content in the uppermost layer of peat is high. As shown in Tables I and I1 and Figure 4, the lignin rapidly drops from a relatively high percentage, 36 to 44 per cent a t the surface, to a low point, between 10 and 12 per cent, just below the middle of the deposit in the moss-peat zone; at the 1.83-meter (6-foot) level in the horizon of the grass-sedge-reed peat the lignin content again suddenly rises to a high point of more than 30 per cent, owing to a high state of preservation of this zone; it then decreases to less than 10 per cent a t the bottom. ALKALI-SOLUBLE MATTER-The alkali-soluble matter comprises essentially the humins. These are the most important and interesting components, as they constitute the main contributors to coal.

Soluble, apparently fulvic.

I

Precipitated with HCI Precipitate

;re

NaoH Residue

Pyridine soluble

I

Pyridine insoluble Figure 6-Separation

of Humins

The complete procedure, beginning with peat, is outlined in flow sheet of Figure 6. CELLULOSE COXTENT-AS in the lignin content, and for the same reason, the cellulose content is high in the surface layer, being more than 40 per cent. From this it rapidly falls to a low figure of 2 to 10 per cent in the: lower horizon of the woody peat. I n the moss-peat layer the cellulose again rises to over 20 per cent to the cehlose-resistant mosses. It is still high in the better preserved grass-reed peat layer, in which it falls to none or merely a trace. Tables I and I1 and Figure 7 give results of analyses.

ANALYTICAL EDITION

220

Comparison of Lignin, Cellulose, a n d H u m i n Curves

If we had to deal with peat derived from decomposing wood done, it would be simple to establish a clear relation between the three components, lignin, cellulose, and humins; unfortunately, we have a large number of other plant substances to consider, such as the remains of leaf tissues, bark, fungi, algae, liverworts, mosses, and lichens, whose tissues

DEPTH,METERS Figure 7-Cellulose

Content of Peat in Relation to Depth

VOl. 1, No. 4

of the lignin curves, but not with the cellulose curves; the first high points of the humin curves approximately coincide with the high cellulose point in the moss-peat zone, The questions now naturally arise-what becomes of the lignin and cellulose and what is the source of the increasing humins? Unfortunately, as already indicated, the analyses give no definite clues, because of the many and varied substances that have contributed. Both lignin and cellulose decrease in general toward the deeper strata and the humin increases proportionately. It can therefore be argued that both are contributors. Experiments on decomposing wood have shown that the cellulose in it disappears, decomposing mainly into water and carbon dioxide, while the lignin is transformed into the so-called humins. Cellulose, when subjected to the action of microorganisms, does not form humins directly. The bodies of the organisms, however, formed synthetically during the decomposition of cellulose, give rise to humin in definite proportions (8). From such experiments and others it is assumed that the humins are derived primarily from the lignin in woody tissues. The steady increase in the insoluble matter, consisting chiefly of spore, pollen, and cuticle matter, is explained by the fact that these components are veryresistant to all kinds of reactions, and will therefore concentrate and remain undecomposed and accumulate as the other materials gradually

are quite different in chemical composition from that of wood. But it is safe to say that wood is the largest contributor and there should be some harmony in the data found. As will be noted, data obtained in the first foot of the material are erratic. This is due to a faulty selection of samples for analysis. More uniform results would have been obtained if an area of several square feet had been selected at a particular level, and the whole thoroughly mixed, from which the sample for analysis could be selected, a method now pursued. I n the deeper horizons, where the peat 5 was more highly macerated and more uniformly 8 10 matured, the analyses are more uniform. However, if the data are averaged, the trend of the 0 average curve is evident. The data show disDEPTH,METERS tinctly that the lignin and cellulose decrease toFigure &--Insoluble Material i n Peat i n Relation t o Depth gether, but the lignin content remains higher than the cellulose content, and the humin content increases in- decompose more and more and are totally lost to the deversely . posit. Tables I and I1 and Figure 8 give results of deterThe cellulose curves take a steady decline until the moss minations. peat layer is reached where, owing to the resistant mossLiterature Cited cellulose, a sharp incline is noted. This agrees with the (1) Allen’s Commercial Organic Analysis, Vol 11, P. Blakiston’s Son 8r analysis of peats by other investigators (9). Froln Co., Philadelphia, 1924. now on the cellulose gradually disappears. (2) Flscher and Schrader, Brennstof-Chem , 3, 37 (1922). ( 3 ) Fuchs, I b t d , 8, 324 (1927). The lignin curve rapidly falls from a high point, then it (4) Hawley and Wise, “Chemistry of Wood,” Chemlcal Catalog co , New flattens and continues to fall through the moss layer, but York, 1926 rises rapidly again on entering the grass-reed-peat complex, ( 5 ) Marcusson, angew, C h e m , 35, 165 (1922) owing to its high resistivity in lignin, to a high point Of 36 to ( 6 ) Oden, Brennstof-Chem , 7, 165 (1926). (7) Schorger, “Chemistry of Cellulose and Wood,” McGraw-Hill Book 44 per cent; from here it falls to less than 10 per cent. Co , New York, 1926 The curves obtained from the data of the humin content (8) Waksman pvoc Intevn sozl scz, 293 (1928). to the lignin content* The first high rise (9) Waksman and Stevens, Sozl Scz , 26, 113, 239 (1928). points of the humin curves coincide with the first 10%’pOilltS ( i o ) Wnksman and Tenny, I b t d , 24, 275 (1927)

r

Wider Use for Inferior Wood An annual saving of 113,000 acres of standing timber would result if the 33,000 carloads of non-utilized wood developed in North Carolina each year should he put to proper use, the committee on wood utilization, Department of Commerce, announced. In its report on a survey conducted in North Carolina, the committee urges sawmills to establish by-products industries involving the utilization of sawdust in the manufacture of pulp, paper, wood chemicals, and similar products. The committee has already completed a similar survey in Virginia and another is in progress in Maryland. The investigation in each case covers only such waste-wood items as are not being put to profitable use, even for fuel.

The bulletin on the North Carolina survey discusses in detail the recognized methods for reducing wood waste, and also brings out important points in connection with the utilization of wood waste unavoidably produced. It gives a detailed account of this wood waste in North Carolina, enumerates the names of the mills by counties, and, in each instance, gives an accurate description of the number of carloads of wood waste available a t every plant and the kind of wood, both as to species and type of waste. The “Survey of Non-Utilized Wood in North Carolina” may be obtained from the Superintendent of Documents, Government Printing Office, Washington, D. C., a t 20 cents per copy.